Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A system for generating a self-receive signal comprising: a signal generator configured to generate a signal at a transmit voltage; a signal processor comprising an analog-to-digital converter characterized by an input noise floor and an input saturation voltage; an antenna characterized by an antenna impedance; a passive coupling device: characterized by a characteristic impedance; comprising an antenna port electromagnetically coupled to the antenna; comprising a transmit port electromagnetically coupled to the signal generator; and comprising a receive port electromagnetically coupled to the signal processor; an impedance matching network: electromagnetically interposed between the antenna port and the antenna; and configured to shift the antenna impedance to a load impedance different from the characteristic impedance of the passive coupling device; and the antenna and the passive coupling device cooperating to reflect the signal, transmitted via the transmit port and at the transmit voltage, toward the receive port at a receive voltage between the input noise floor and the input saturation voltage according to a reflection coefficient effected by a difference between the load impedance and the characteristic impedance.
2. The system of claim 1 : further comprising a first node comprising: the signal generator; the signal processor; the antenna; the passive coupling device; and the impedance matching network; further comprising a second node comprising: a second signal generator configured to generate a signal at a second transmit voltage; a second signal processor comprising a second analog-to-digital converter characterized by a second input noise floor and a second input saturation voltage; a second antenna characterized by a second antenna impedance; a second passive coupling device: characterized by a second characteristic impedance; comprising a second antenna port electromagnetically coupled to the second antenna; comprising a second transmit port electromagnetically coupled to the second signal generator; and comprising a second receive port electromagnetically coupled to the second signal processor; a second impedance matching network: electromagnetically interposed between the second antenna port and the second antenna; and configured to shift the second antenna impedance to a second load impedance different from the second characteristic impedance of the second passive coupling device; and the second antenna and the second passive coupling device cooperating to reflect the signal, transmitted via the second transmit port and at the second transmit voltage, toward the second receive port at a second receive voltage between the second input noise floor and the second input saturation voltage according to a second reflection coefficient effected by a difference between the second load impedance and the second characteristic impedance; and wherein the first node and the second node are configured to execute a two-way time synchronization protocol by: at the first node: transmitting a first synchronization signal; and generating a first self-receive signal based on the first synchronization signal via reflection by the antenna and the passive coupling device; at the second node: transmitting a second synchronization signal; and generating a second self-receive signal based on the second synchronization signal via reflection by the second antenna and the second passive coupling device; at the first node: calculating a first time-of-arrival of the first self-receive signal; and calculating a second time-of-arrival of the second synchronization signal; at the second node: calculating a third time-of-arrival of the second self-receive signal; and calculating a fourth time-of-arrival of the first synchronization signal; and calculating a time bias and a propagation delay between the first node and the second node based on the first time-of-arrival, the second time-of-arrival, the third time-of-arrival, and the fourth time-of-arrival.
3. The system of claim 1 , wherein the impedance matching network is further configured to shift the antenna impedance of the antenna to the load impedance equal to a function of the transmit voltage, a desired signal voltage between the input noise floor and the input saturation voltage, a coupling factor of the passive coupling device and proportional to the characteristic impedance of the passive coupling device.
4. The system of claim 3 , further comprising the impedance matching network configured to shift the antenna impedance of the antenna to the load impedance equal to: Z L = ( 1 + b 1 a 1 C ) ( 1 - b 1 a 1 C ) Z s , wherein a 1 represents the transmit voltage, b 1 represents the desired signal voltage, C represents the coupling factor of the passive coupling device, and Z s represents the characteristic impedance of the passive coupling device.
This invention relates to wireless power transmission systems, specifically addressing the challenge of efficiently transferring power between a transmitter and a receiver using a passive coupling device. The system includes an antenna, a passive coupling device, and an impedance matching network. The passive coupling device facilitates wireless power transfer by coupling energy between the transmitter and receiver. The impedance matching network is designed to optimize power transfer by adjusting the antenna impedance to match the load impedance, ensuring maximum efficiency. The load impedance is calculated using a formula that incorporates the transmit voltage, desired signal voltage, coupling factor of the passive coupling device, and the characteristic impedance of the passive coupling device. This adjustment compensates for variations in coupling efficiency and ensures stable power delivery. The system improves wireless power transmission by dynamically adapting to changing conditions, reducing energy loss, and enhancing overall system performance. The invention is particularly useful in applications requiring reliable and efficient wireless power transfer, such as consumer electronics, medical devices, and industrial equipment.
5. The system of claim 1 : wherein the impedance matching network further comprises a switchable wideband matching network defining a set of impedance matching networks, each impedance matching network in the set of impedance matching networks configured to maintain the load impedance for a frequency band of the signal; and further comprising a controller configured to actuate a switch in the switchable wideband matching network between the set of impedance matching networks.
6. The system of claim 5 , further comprising the controller configured to actuate a switch in the switchable wideband matching network between the set of impedance matching networks based on a frequency band of the signal.
A system for radio frequency (RF) signal transmission includes a switchable wideband matching network designed to optimize impedance matching across multiple frequency bands. The system addresses the challenge of maintaining efficient power transfer and minimizing signal reflections in RF circuits when operating across different frequency ranges. The switchable wideband matching network comprises a set of impedance matching networks, each tailored to a specific frequency band. A controller dynamically selects the appropriate impedance matching network by actuating a switch within the network based on the frequency band of the transmitted or received signal. This ensures optimal impedance matching for the given frequency, improving signal integrity and system performance. The controller monitors the signal frequency and adjusts the switch configuration in real-time to maintain efficient operation across varying frequency bands. This approach enhances the versatility and efficiency of RF systems, particularly in applications requiring multi-band operation, such as wireless communication devices and radar systems. The system eliminates the need for manual adjustments or fixed matching networks, providing a more adaptable and automated solution for impedance matching in RF applications.
7. The system of claim 1 , further comprising the controller configured to actuate a switch in the switchable wideband matching network between the set of impedance matching networks based on an signal-to-noise ratio of a self-receive signal, generated via reflection of the signal, received by the analog-to-digital converter.
8. The system of claim 1 : wherein the impedance matching network further comprises a multiplexed matching network defining a set of impedance matching networks, each impedance matching network in the set of impedance matching networks configured to maintain the load impedance for a frequency band of the signal; and further comprising a controller configured to select a matching network in the set of impedance matching networks via a multiplexer in the multiplexed matching network.
9. The system of claim 1 , wherein the passive coupling device further comprises a directional coupler comprising: an input port electromagnetically coupled to the antenna; a transmitted port electromagnetically coupled to signal generator; and a coupled port electromagnetically coupled to the signal processor.
10. The system of claim 1 , wherein the passive coupling device further comprises a power divider comprising: an input port electromagnetically coupled to the antenna; a first divider port electromagnetically coupled to the signal generator; and a second divider port electromagnetically coupled to the signal processor.
This invention relates to wireless communication systems, specifically a passive coupling device for managing signal transmission and reception in a shared antenna system. The problem addressed is the need to efficiently distribute and process signals in a system where a single antenna is used for both transmitting and receiving signals, often requiring isolation between the transmitter and receiver to prevent interference. The passive coupling device includes a power divider that splits an incoming signal from the antenna into two separate paths. The power divider has an input port connected to the antenna, a first divider port connected to a signal generator (transmitter), and a second divider port connected to a signal processor (receiver). This configuration allows the antenna to simultaneously transmit and receive signals without direct coupling between the transmitter and receiver, reducing interference and improving signal integrity. The power divider ensures that transmitted signals from the signal generator are directed to the antenna while received signals from the antenna are routed to the signal processor, maintaining isolation between the two paths. This design is particularly useful in applications where space or cost constraints limit the use of multiple antennas or active components.
11. The system of claim 1 , wherein the passive coupling device further comprises a circulator comprising: a first circulator port electromagnetically coupled to the antenna and configured to couple signals to a second circulator port; the second circulator port electromagnetically coupled to the signal processor and configured to couple signals to a third circulator port; and the third circulator port electromagnetically coupled to the signal generator and configured to couple signals to the first circulator port.
12. A system for generating a self-receive signal comprising: a signal generator configured to generate a signal at a transmit voltage; a signal processor comprising an analog-to-digital converter characterized by an input noise floor and an input saturation voltage; an antenna characterized by an antenna impedance; a passive coupling device: characterized by a characteristic impedance; comprising an antenna port electromagnetically coupled to the antenna; comprising a transmit port electromagnetically coupled to the signal generator; and comprising a receive port electromagnetically coupled to the signal processor; and an impedance matching network: electromagnetically interposed between the antenna port and an antenna; configured to reflect the signal from the signal generator at the transmit voltage toward the signal processor at a receive voltage between the input noise floor and the input saturation voltage; and configured to transform the antenna impedance of the antenna to a load impedance, the load impedance of the antenna and the characteristic impedance of the passive coupling device cooperating to reflect the signal from the signal generator and at the transmit voltage toward the signal processor at the receive voltage.
13. The system of claim 12 , wherein the impedance matching network is further configured to transform the antenna impedance of the antenna to the load impedance equal to a function of the transmit voltage, the receive voltage, a coupling factor of the passive coupling device and proportional to the characteristic impedance of the passive coupling device.
14. The system of claim 13 , wherein the impedance matching network is further configured to transform the antenna impedance of the antenna to the load impedance equal to: Z L = ( 1 + b 1 a 1 C ) ( 1 - b 1 a 1 C ) Z s , wherein a 1 represents the transmit voltage, b 1 represents a desired signal voltage between the input noise floor and the input saturation voltage, C represents a coupling factor of the passive coupling device, and Z s represents the characteristic impedance of the passive coupling device.
This invention relates to impedance matching networks for antenna systems, specifically addressing the challenge of optimizing signal transmission efficiency by dynamically adjusting impedance to match varying load conditions. The system includes an antenna with a variable impedance and a passive coupling device that facilitates signal transmission while minimizing reflections and losses. The impedance matching network is configured to transform the antenna impedance to a specific load impedance, calculated as Z L = (1 + b1/a1 * C) / (1 - b1/a1 * C) * Z s. Here, a1 represents the transmit voltage, b1 is the desired signal voltage between the input noise floor and the input saturation voltage, C is the coupling factor of the passive coupling device, and Z s is the characteristic impedance of the passive coupling device. This transformation ensures that the system operates efficiently by maintaining optimal power transfer between the antenna and the load, even under varying signal conditions. The passive coupling device, such as a transformer or directional coupler, enables precise control over the impedance transformation without requiring active components, reducing complexity and power consumption. The system is particularly useful in wireless communication devices where signal integrity and power efficiency are critical.
15. The system of claim 12 : wherein the impedance matching network further comprises a switchable wideband matching network defining a set of impedance matching networks, each impedance matching network in the set of impedance matching networks configured to reflect the signal for a frequency band in a set of frequency bands of the signal; and further comprising a controller configured to actuate a switch in the switchable wideband matching network between the set of impedance matching networks.
16. The system of claim 12 : wherein the impedance matching network further comprises a multiplexed matching network defining a set of impedance matching networks, each impedance matching network in the set of impedance matching networks configured to reflect the signal for a frequency band in a set of possible frequency bands of the signal; and further comprising a controller configured to select a matching network in the set of impedance matching networks via a multiplexer in the multiplexed matching network.
This invention relates to impedance matching networks for signal transmission systems, particularly in wireless communication or RF applications where efficient power transfer is critical. The problem addressed is the need for adaptive impedance matching across multiple frequency bands to optimize signal reflection and power transfer efficiency. Traditional fixed impedance matching networks are ineffective when operating across varying frequency bands, leading to signal loss and reduced performance. The system includes a multiplexed impedance matching network that comprises a set of individual impedance matching networks, each designed to optimize signal reflection for a specific frequency band within a broader range of possible operating frequencies. A multiplexer selectively connects one of these matching networks to the signal path based on the current operating frequency band. A controller dynamically selects the appropriate matching network via the multiplexer, ensuring optimal impedance matching for the given frequency band. This adaptive approach minimizes signal reflection and maximizes power transfer efficiency across multiple frequency bands, improving overall system performance. The system is particularly useful in applications requiring broadband or multi-band operation, such as modern wireless communication devices.
17. A system for generating a self-receive signal comprising: a signal generator configured to generate a signal at a transmit voltage; a signal processor comprising an analog-to-digital converter characterized by an input noise floor and an input saturation voltage; an antenna characterized by an antenna impedance; a passive coupling device: characterized by a characteristic impedance; comprising an antenna port electromagnetically coupled to the antenna; comprising a transmit port electromagnetically coupled to the signal generator; and comprising a receive port electromagnetically coupled to the signal processor; and an impedance matching network: electromagnetically interposed between the antenna port and an antenna; and configured to transform the antenna impedance of the antenna to a load impedance, the load impedance configured to reflect signals transmitted from the transmit port and at the transmit voltage toward the receive port at a receive voltage between the input noise floor and the input saturation voltage.
18. The system of claim 17 , wherein the impedance matching network is further configured to transform the antenna impedance of the antenna to the load impedance equal to a function of the transmit voltage, the receive voltage, a coupling factor of the passive coupling device and proportional to the characteristic impedance of the passive coupling device.
19. The system of claim 18 , wherein the impedance matching network is further configured to transform the antenna impedance of the antenna to the load impedance equal to: Z L = ( 1 + b 1 a 1 C ) ( 1 - b 1 a 1 C ) Z s , wherein a 1 represents the transmit voltage, b 1 represents the receive voltage, C represents a coupling factor of the passive coupling device, and Z s represents the characteristic impedance of the passive coupling device.
Unknown
January 26, 2021
Browse 5M+ US patents with plain-English claim translations and AI-generated analysis.